Understanding True Potential

Hello everyone! Today's video delves into the fascinating world of pure potential and how we can harness it to our advantage. We'll be diving deep into Tesla's one-wire system to generate a potent high-voltage electrostatic potential. Though this effect is achievable at any voltage, to truly discern a stark contrast with the ambient electrical potentials, one requires incredibly high voltages. Perhaps this is why mainstream science often overlooks this methodology. Remember, you won't get far by merely connecting a meter to your standard 110V AC without a return path.

However, in this video, I will unravel certain techniques to overcome this challenge. I'll walk you through how the current mainstream understanding emphasizes the use of pure current, potentially sidelining other potent avenues.

By leveraging the one-wire system, we can transform these electrostatic potentials into actual work. Think pulsed DC that's capable of charging up capacitors or even powering small to medium-sized AC appliances. If you're aiming for more juice, just scale the setup! The beauty is that it doesn't demand any substantial input power surge. Dive into the video for a comprehensive breakdown!

But here's a curveball: isn't this just another variant of 'wireless' charging or RF? Well, in essence, high frequencies are indeed RF, instrumental in engendering proximate electrostatic potentials. Instead of viewing it as a byproduct, we employ it as our core trigger mechanism. Whereas conventional wireless charging systems can burden the primary side, thanks to the receiver loop's effects, we've sidestepped this pitfall. Tesla's vision of wireless power was genuinely groundbreaking! And no one does it properly!

In our configuration, we ensure the output loop remains perpetually open, incurring only the minimal cost for the primary magnetization of the transformer. By incorporating a reactive stage to the input, we can further diminish the marginal yet present input current load. We're not in the game for traditional current; our objective is solely a trigger, and reactive power is a perfect fit. Our one-wire system, augmented with a dual-diode setup, blesses us with a pulsating DC output, hovering around the 80-100V mark.

The role of diodes here is paramount. We've devised a system where energy, when captured on the secondary side, bifurcates into positive and negative DC components, deviating significantly from conventional loops. This dynamic is captivating!

Our novel "one-wire" system, fortified with diodes on the secondary, paves an exclusive route for energy, feeding capacitors and subsequently, batteries. The isolation from the transformer’s primary ensures the absence of back EMF or counter-loading effects. The result? Minuscule loading on the primary, even while we're siphoning energy on the other end. We can even short out one of our outputs and get no heating on our input, Some refer to this kind of system as "Cold Electricity" and it works on one wire and even some non conductors!

To summarize, the primary gets bogged down only by the transformer's innate losses, blissfully unaware of the energy extraction happening at the secondary, all credit to the isolation we've crafted.

Forum http://typeright.social/forum
Please help support my research https://youtu.be/pYXETBB40j0